about
Narrow bandgap colloidal metal chalcogenide quantum dots: synthetic methods, heterostructures, assemblies, electronic and infrared optical properties.Use of carbon nanotubes (CNTs) with polymers in solar cells.The role of the conjugate bridge in electronic structures and related properties of tetrahydroquinoline for dye sensitized solar cells.Physical electrochemistry of nanostructured devices.Probing dark exciton diffusion using photovoltageFree carrier generation in organic photovoltaic bulk heterojunctions of conjugated polymers with molecular acceptors: planar versus spherical acceptors.Metal oxide semiconductors for dye- and quantum-dot-sensitized solar cells.Recent Advances of Cobalt(II/III) Redox Couples for Dye-Sensitized Solar Cell Applications.Photoresponse of supramolecular self-assembled networks on graphene-diamond interfaces.Smart Electronic Textiles.Photoelectrochemical Properties of Graphene and Its Derivatives.The molecular nature of photovoltage losses in organic solar cells.Multimode simulation of dimer absorption spectra from first principles calculations: application to the 3,4,9,10-perylenetetracarboxylic diimide dimer.Random nanowires of nickel doped TiO2 with high surface area and electron mobility for high efficiency dye-sensitized solar cells.Bragg stack-functionalized counter electrode for solid-state dye-sensitized solar cells.Electronic and charge transfer properties of bio-inspired flavylium ions for applications in TiO2-based dye-sensitized solar cells.Nanowire dye-sensitized solar cells.Stepwise photoconversion of an artificial light-harvesting array built from extended BODIPY units.Two-dimensional exciton properties in monolayer semiconducting phosphorus allotropes.Theoretical studies on organic D-π-A sensitizers with planar triphenylamine donor and different π-linkers for dyes-sensitized solar cells.Long distance energy transfer in a polymer matrix doped with a perylene dye.Exciton dissociation in the presence of phonons: a reduced hierarchy equations of motion approach.Methodological assessment of kinetic Monte Carlo simulations of organic photovoltaic devices: the treatment of electrostatic interactions.Topologically protected excitons in porphyrin thin films.Donor–acceptor single cocrystal of coronene and perylene diimide: molecular self-assembly and charge-transfer photoluminescencePFO-BPy solubilizers for SWNTs: Modelling of polymers from oligomersObservation of bi-polarons in blends of conjugated copolymers and fullerene derivativesOptical Spectroscopy of a Polyfluorene Copolymer at High Pressure: Intra- and Intermolecular InteractionsMorphology controlled open circuit voltage in polymer solar cellsSemiconductor Block Copolymers for Photovoltaic Applicationsn-type organic field effect transistors from perylene bisimide block copolymers and homopolymersSuper-radiance of excitons in a single ZnO nanostructureControlled Morphologies by Molecular Design and Nano-Imprint LithographyA Small Molecule Non-fullerene Electron Acceptor for Organic Solar CellsNonthermally activated exciton transport in crystalline organic semiconductor thin filmsOn the Study of Exciton Binding Energy with Direct Charge Generation in Photovoltaic PolymersElectronic Structures and Optical Properties of Phenyl C71Butyric Acid Methyl EstersSynthetic Strategies and Applications of GaN NanowiresSpectra and Charge Transport of Polar Molecular Photoactive Layers Used for Solar CellsImprovement in charge transfer dynamic of the porphyrin-based solar cells in water: A theoretical study
P2860
Q34567221-C775482E-A432-4BB8-AEBA-A04FDC77E0D0Q35374267-817B95E8-11C1-43A7-831B-CC06FB68C3FAQ36790417-C4483EEF-6FB0-4C77-98DE-338FC10BF370Q37030607-4C988C9D-538C-4BE9-8885-6390CE0096E5Q37622441-0C17A41A-B1C4-4BA5-BCAC-3C15701C34EBQ38193767-68BBD5B7-959D-4343-819D-EA95EF962F5CQ38293856-444F41C6-AEB4-451D-A7C9-75FB99C2240AQ38529812-471ADC78-6749-4E61-AF6B-9AE4ED658639Q38706952-B0094807-C46B-43D6-BBC1-A5980ED5A273Q38785497-DB3156C4-787A-498A-9629-494E8225D174Q38872651-89283FBF-E8DC-464F-B9C8-1C865DFBD22BQ39787711-F904F0EF-5FCC-42B7-B5CB-03FCEC733D89Q43009629-BF1EFC81-4784-4166-B1A6-A6DA76D6BB00Q44165316-F975A064-8BC2-49D7-8F8E-F8CA6D28DA20Q45731281-AB7C352E-7DC3-4192-B82D-6A0F50E2EB68Q46332896-285B9AC3-F733-43B6-AF96-4E76F6EA0272Q46474418-00A6391D-43B5-4F69-AAD1-24E7845191F1Q47831195-5455E22C-0B2F-48DB-8ED3-5E7A91B61EAAQ50196721-5AA77CFC-3EDD-4036-AB76-4C325CBA4A58Q50467880-D20C2F3F-4E50-43E8-B7BC-9E696AF45661Q50549352-8C3FF24E-00CB-4040-A8BE-361E7D9EAA9CQ51102109-60820FC9-472D-41AB-83B4-89E8E9EF84C9Q51715868-52752C75-081A-44FD-ABC1-491B0196A093Q53438896-7C48A123-8720-49B5-A6D1-815FF804AB80Q56387163-680212B1-53CB-47B1-979A-C97E132EB0E3Q57394854-41382F5F-4F4D-4077-B593-E5A22B439B15Q57654055-F0409649-E270-493F-AF1F-E1323D199430Q58012353-108D21AA-A47E-4485-AAC7-3601E61AFEF8Q58231504-DF088783-6277-4217-82CD-0AEDED06E9BDQ58231520-C127DF64-9BA6-4091-BC80-375E30175F80Q58231543-92AE23BD-3187-484B-BBB4-52F9D986A208Q58277421-C47C05B8-B2BA-4F9F-99CD-31170C37776DQ58338117-70282D78-FD57-42A5-A330-87609753DF5FQ58452143-1801B901-48DE-4937-BFC3-678A9A42B39CQ58589590-024ADDEC-79B1-4D31-BFDE-78EF2934735EQ58621012-449D40D8-8EF2-4A1A-8864-1C55D9B2A4BDQ59017098-88483517-DD46-44B9-A58F-85CDA474D04DQ59044218-501595EE-6291-4AF0-BBFE-245FB9AED1C6Q59112273-C3407B07-682E-4411-8680-054E9058A34AQ59243341-6A7F83F4-AC04-4A52-84E5-2E2A7B9DFE71
P2860
description
im Mai 2003 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в травні 2003
@uk
name
Excitonic Solar Cells
@en
Excitonic Solar Cells
@nl
type
label
Excitonic Solar Cells
@en
Excitonic Solar Cells
@nl
prefLabel
Excitonic Solar Cells
@en
Excitonic Solar Cells
@nl
P356
P1476
Excitonic Solar Cells
@en
P2093
Brian A. Gregg
P304
P356
10.1021/JP022507X
P407
P577
2003-05-01T00:00:00Z